PL201287B1 - Method of fabricating of liquid fertilizer - Google Patents

Abstract

Concentrated liquid fertilizer in the form of a solution that contains 24 ± 1 wt.% total nitrogen and 8 ± 0.5 wt.% P2O5 and is characterized by a polyphosphate content in the range of 50 - 80% of the total phosphates, preferably 55 - 70%, and optionally a suitable amount of water to maintain the composition, and optionally contains boron. The method for producing concentrated liquid fertilizer consists in obtaining a fertilizer by mixing a urea-ammonium nitrate solution with a nitrogen content of 28 - 32 wt.% with an ammonium polyphosphate solution with a fertilizer composition of 10 - 12 wt.% nitrogen N and 30 - 38 wt.% phosphorus as P2O5, preferably 33 - 37% and optionally boron is introduced, wherein the polyphosphate solution is obtained by neutralization of thermal polyphosphoric acid with the chemical formula Hn+2PnO3n+1, and P2O5 content of 75 - 80% with ammonia water with ammonia NH3 content of 22 - 25.5% in a water-cooled reactor - mixer so that the process temperature does not exceed 70°C, and preferably the neutralization temperature is in the range of 40° - 50°C.

Description

(12) PATENT DESCRIPTION (19) PL (11) 201287 (13) B1 ( ²¹ ) Application number: ³⁷¹⁷²¹ ( ¹ ) )

C05C 13/00 (2006.01) C05C 3/00 (2006.01) C05G 1/06 (2006.01) (22) Filing date: 13/12/2004 (54) Concentrated liquid fertilizer and method for producing liquid fertilizer

(73) Patent holder: (43) The application was announced: Institute of Chemistry, Gliwice, Poland 26.06.2006 BUP 13/06 (72) Inventor(s): (45) The patent was granted on: 31/03/2009 WUP 03/09 Bztbztz Cichy, Gliwice, PL Witold Gtzcbisz, Pkznzń, PL Stanisław Fklck, Gliwice, PL

(57) a recently developed liquid fertilizer containing 24 ± 1 wt.% total nitrogen and 8 ± 0.5 wt.% P2O5 and characterized by a polyphosphate content in the range of 50 - 80% of the total amount of phosphates, preferably 55 - 70%, and optionally an appropriate amount of water to maintain the composition, and optionally containing boron. The method for producing a concentrated liquid fertilizer consists in obtaining a fertilizer by mixing a urea-ammonium nitrate solution with a nitrogen content of 28 - 32 wt.% with an ammonium polyphosphate solution with a fertilizer composition of 10 - 12 wt.% nitrogen N and 30 - 38 wt.% phosphorus as _P2O5 , preferably 33 - 37%, and optionally boron is introduced, wherein the polyphosphate solution is obtained by neutralization of thermal polyphosphoric acid with the chemical formula Hn ₊ 2PnO3 _n +1 and _P2O5 content of 75 - 80% with ammonia water with ammonia NH3 content of 22 - 25.5% in a water-cooled reactor-mixer so that the process temperature does not exceed 70°C, and preferably the neutralization temperature is in the range of 40° - 50°C.

PL 201 287 B1

Description of the invention

The subject of the invention is a liquid fertilizer and a method for producing a liquid, concentrated multi-component fertilizer in the form of a solution, intended for soil application.

Liquid fertilizers have highly specific physical and chemical properties, the most noteworthy of which are:

- Low salt index value; thanks to this, the fertilizer used does not damage the germinating seeds.

- Good solubility of nutrients in water; this feature is directly related to the speed of the fertilized plant's response to the added nutrient.

- Easy application.

It is particularly desirable for liquid fertilizers to exhibit a pH close to neutral. This pH allows for use in a variety of soil conditions and on a variety of substrates. The chemical and physical formulation of liquid fertilizers should be designed to prevent precipitation. A relatively wide temperature range and a relatively long period during which the solution maintains the stability of the established and intended chemical composition are important. These conditions are perfectly met by the urea-ammonium nitrate solution, produced on a commercial scale and well-known and used in agricultural practice. This is a nitrogen-only fertilizer, sometimes enriched with sulfur or magnesium. Using urea-ammonium nitrate solution solves the problem of pre-sowing nitrogen fertilization of the soil and supplementing plants with nitrogen when necessary.

The problem of liquid phosphorus fertilization is more difficult to solve. Phosphorus, as a primary fertilizer nutrient, is essential for plants, shortens the growing season, primarily affects plant root systems, and in the case of cereals, also grain yield. Due to the poor solubility of phosphates in water, especially in the presence of trace elements or in hard water, acidic solutions are most often used in liquid form, which is unfavorable for many plants and soils. Plants absorb phosphorus in the form of the H2PO4 ion, which occurs in soils with a pH below 7.0.

Easily available phosphorus increases plant tolerance to stress caused by:

- water shortage (drought);

- excessive soil acidification;

- attack by pathogens.

The proposed solution involves introducing phosphorus into a well-known liquid fertilizer – a urea-ammonium nitrate solution – in the form of ammonium polyphosphate with appropriately selected properties. These properties result from maintaining the ammonium polyphosphate synthesis parameters and the quality of the input raw materials used in this process.

The conversion of polyphosphates to orthophosphates is stimulated by pyrophosphatase enzymes, usually present in significant quantities in the soil. Therefore, this process is strongly dependent on factors controlling the biological activity of the soil (organic matter content, pH, temperature). Fertilizer applied in solution, through extensive contact with the soil in the plant's rooting zone, creates conditions for significant phosphorus utilization by treated plants, regardless of the species and their use. The half-life of polyphosphates ranges from 1 to 100 days, with an average of approximately 18 days. It can be assumed that within two weeks of application, the nutrient in an amount sufficient to meet the plant's needs is converted to orthophosphate forms (according to G. Rehm, Orthophosphates and Polyphosphate: Is the Difference, Minnesota Crop News, University of Minnesota MNLN 53, 2002 and R. Lohry, Ortho versus Poty, Nutra-FLO Company, 2001). The use of ammonium polyphosphate solutions in liquid fertilization is known. Polyphosphates are most often used to increase the concentration of fertilizer components in solutions and to improve the solubility of certain micronutrients added as cations, particularly in phosphorus-potassium fertilizers or NPK liquid fertilizer solutions - Polish patent description 167516, US 5,707,418, Polish patent application P 340609.

The concentrated liquid fertilizer according to the invention contains 24±1% by weight of total nitrogen and 8±0.5% by weight of P2O5 and is characterized by a polyphosphate content in the range of 50-80% of the total amount of phosphates, preferably 55-70%, and optionally an appropriate amount of water to maintain the composition, and optionally contains boron.

The method according to the invention consists in obtaining a fertilizer by mixing a urea-ammonium nitrate solution with a nitrogen content of 28-32% by weight with an ammonium polyphosphate solution with the composition

PL 201 287 B1 fertilizer solution of 10-12 wt.% nitrogen N and 30-38 wt.% phosphorus as _P2O5 , preferably 33-37%, and optionally boron is introduced, wherein the polyphosphate solution is obtained by neutralization of thermal polyphosphoric acid of the chemical formula H _n+ 2PnO3 _n +1, and P2O5 content _of 75-80% with ammonia water with ammonia NH3 content of 22-25.5% in a water-cooled reactor-mixer so that the process temperature does not exceed 70°C, and preferably the neutralization temperature is in the range of 40°-50°C, and boron is introduced into the fertilizer solution in the form of orthoboric acid in the amount of 0.1-5.0 wt.%.

Neutralization is carried out until pH is in the range of 5.5-7.0, preferably 6.0-6.5. The obtained fertilizer solution A is characterized by a total phosphorus content as P2O5 of 30-38%, most preferably 33.5-37.0%, and an ammonium nitrogen content of 10-12% by mass and a polyform content (condensed phosphates with n > 2) of 50-80% of the total phosphate content, preferably 55-70%.

The fertilizer solution A thus obtained is added to a commercial urea-ammonium nitrate solution (UAN) with a total nitrogen content of 28-32%, maintaining the following weight proportions.

Fertilizer A (ammonium polyphosphate solution) 21-26 parts by weight

UAN (28-32) - 66-78 parts by weight

Water - 0-12 parts by weight

Formulations are designed to achieve a final fertilizer composition of 24±1% nitrogen as N and 8±0.5% P2O5. The mixing process is conducted without heating or cooling. The accompanying endothermic effect is minimized by slowly dosing the polyphosphate into the UAN solution so that excessive cooling does not adversely affect the solubility of the components and salt them out of the solution. For the use of this fertilizer formula in fertilizing certain plants, it is beneficial to enrich it with boron. The introduction of this trace element in the form of orthoboric acid has proven particularly beneficial. This form of boron introduction has proven to be very advantageous, as the solubility of orthoboric acid in an ammonium polyphosphate solution with the properties indicated above is greater than its solubility in water, provided the dissolution process is conducted at a temperature of 35-50°C. This temperature is particularly favorable for the neutralization of polyphosphoric acid with ammonia without the unfavorable hydrolysis of the polyphosphate forms.

The production method according to the invention is described by way of example.

Example 1

To 662 g of 25% NH3 ammonia water at ambient temperature was slowly dosed, with continuous, intensive stirring, 445 g of thermal polyphosphoric acid with a total _P2O5 content of 79%. The process was carried out in a reactor with a working capacity of V = 1.5 ^dm3 equipped with an open turbine mixer, a cooling coil, a thermometer, and a continuously operating pH meter. Cooling intensity was regulated to maintain the neutralization process temperature at 40-50°C. The final product, the 10-34-0 stock solution, had the following properties:

P2O ₅ total content 34.04% P2O ₅ ortho content 9.5% P2O ₅ pyro content 13.3% P2O ₅ tripoly content 9.09% conversion factor K = ^Ρζ θ ^{5 non-ortho} _ 72.1%

P2O5 total

N content 9.7% pH 6.2 ^{density 1366} kg/m ³ 220°C) crystallization temperature -18°C

To 770 g of a commercial urea-ammonium nitrate solution with a total nitrogen content of 28% was added, with continuous stirring, 230 g of the 10-34-0 base solution prepared as described above. During the mixing process, a 3°C increase in temperature was observed. This resulted in 1000 g of a fertilizer solution with the following composition and properties:

Total P2O5 content _8.15 %

The proportion of polyphosphates in the total amount of phosphates (degree of conversion) is 70%

Total nitrogen content (N) 24%

PL 201 287 B1 nitrogen in ammonium form 7.7% amide 11.1% nitrate 5.2% pH 6.5 crystallization temperature -1°C density 1.32 g/l Example 2

To 1000 g of the fertilizer solution obtained as described in Example 1, 100 g of solid orthoboric acid was added and mixed for 15 minutes.

Claims (3)

Patent claims 1. Concentrated fertilization of the pathway in the rootstock, changed in that it contains 22 ± 1% of weight. % of total aase and 8 ± 0.5 wt. P2O5 and is characterized by a polyphosphate content in the range 50-80% of the total phosphate, preferably 55-70%, and optionally contains sufficient water to maintain its composition, and optionally contains boron. 2. The method of treating liquid nitrogen, characterized by the fact that you are sucked by the fertilizer by mixing a nitrate-urea solution with a nitrogen content of 28-32% by weight. with an ammonium polyphosphate solution with a fertilizer composition of 10-12% by weight % nitrogen N and 30-38 wt.%. phosphorus as P2O5, preferably 33-37%, and optionally boron is introduced, the polyphosphate solution is obtained by neutralizing the thermal polyphosphoric acid with the chemical formula Hn + 2PnO3n ₊ 1, and the P2O5 content of 75-80% with ammonia water with ammonia content of NH3 22- 25.5% in the reactor-agitator cooled with water so that the process temperature does not exceed 70 ° C, and preferably the neutralization temperature is in the range ± 0 ° -50 ° C. 3. watwaruania nawoou οϊβΜθοο according to Zajso. 2. A method according to claim 2, characterized in that the bon j ^ ^ s is introduced into the fertilizing solution 2 + - 8 - 0 in the form of orthoboric acid in the amount of 0.1 - 5.0 wt.%. Publishing Department of the Polish Patent Office